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Hepatitis B core antigen based novel vaccine against porcine epidemic diarrhea virus
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Journal of Virological Methods journal homepage: www.elsevier.com/locate/jviromet
Hepatitis B core antigen based novel vaccine against porcine epidemic diarrhea virus Frank Gillama, Jianqiang Zhangb, Chenming Zhanga, a b
⁎
Department of Biological Systems Engineering, Virginia Tech, 1230 Washington St. SW, Blacksburg, VA 24061, USA Department of Veterinary Diagnostic and Production Animal Medicine, Iowa State University, Ames, IA, USA
A R T I C L E I N F O
A B S T R A C T
Keywords: HBcAg PEDV Vaccine VLP Purification
Porcine epidemic diarrhea Virus (PEDV) is the causative agent of porcine epidemic diarrhea, which is a devastating viral disease and causes severe economic loss to the swine industry. Current vaccine options for PEDV include modified live viruses and killed live viruses. Though these vaccines have shown efficacy, some have side effects including viral shedding. This report details an E. coli based expression and purification process of multiple vaccine candidates for PEDV using Hepatitis B Core Antigen (HBcAg) as a backbone protein. Short linear peptide sequences from PEDV were inserted into the immunodominant region of HBcAg in a novel recombinant vaccine design against PEDV. These peptide sequences were successfully inserted individually as well as all together in a multivalent strategy. Each vaccine candidate was tested in vivo in an intranasal as well as an intraperitoneal administration. Although each candidate was able to elicit a strong immunogenic response specific for the inserted peptide sequences, only two out of five of the test candidates demonstrated an ability to elicit an immune response capable of virus neutralization when delivered via intraperitoneal administration in mice.
1. Introduction Porcine epidemic diarrhea Virus (PEDV) is a member of the Alphacoronavirus genus in the Coronaviridae (CV) family in the Nidovirales order. The genome of PEDV is approximately 28 kb in length and incudes 5′ and 3′ untranslated regions and 7 known open reading frames (ORFs) in the order of ORF1a, ORF1b, spike (S) protein, ORF3, envelope (E) protein, membrane (M) glycoprotein, and nucleocaspid (N) protein (Song and Park, 2012). PEDV was first discovered in Europe in the 1970s and spread to Asia in the 1980s and 1990s (Song and Park, 2012; Pensaert and de Bouck, 1978). PEDV was detected for the first time in North America in 2013 and caused severe disease and substantial economic losses (Stevenson et al., 2013; Cima, 2014). The symptoms of PEDV are watery diarrhea, depression, and anorexia. The high mortality rate of PEDV in suckling piglets is caused by the destruction of susceptible microvilli in the small intestine (Madson et al., 2014). The fecal-oral route of infection has the highest rate of transmission, although evidence suggests that airborne aerosolized virus may also be infectious (Alonso et al., 2014). Even though vaccines currently exist for PEDV in killed virus (KV) and modified live virus
(MLV) formats, there are side effects from their administration. A recombinant vaccine strategy may therefore be more appropriate for PEDV in agriculture. Hepatitis B Core Antigen (HBcAg) is the nucleocapsid protein from the Hepatitis B virus. The native form of the protein is 183 amino acids (AA) in length and has the ability to self-assemble into the nucleocapsid structure with a diameter around 30 nm (Cohen and Richmond, 1982; Bottcher et al., 1997). The full protein consists of two domains, only the first of which is required for self-assembly of the protein (Wingfield et al., 1995; Tan et al., 2003). Recombinant versions of the protein typically consist of only the first 149 AA and are abbreviated as ΔHBcAg. Genetic manipulation of ΔHBcAg has been demonstrated previously in vaccine designs, some of which have been approved for use in humans in the US (Schodel et al., 1994a; Schodel et al., 1994b; Schodel et al., 1996; Yang et al., 2017). Short linear epitopes from other viruses are often inserted at AA P80, which can be done with successful self-assembly and subsequent foreign antigen presentation provided that the peptide insertion does not cause sever steric hindrance through secondary or tertiary structure. This location within the protein has been shown to induce the highest immune response and is considered to
Abbreviations: PEDV, porcine epidemic diarrhea virus; EFP, ELISA fusion protein; Ab, antibody; HBcAg, hepatitis B Core antigen; VLP, virus like particle; VN, virus neutralization; PS, polystyrene; GST, glutathione-S-transferase; AEX, anion exchange; IMAC, immobilized metal affinity chromatography; IPTG, isopropyl β-D-1-thiogalactopyranoside; DLS, dynamic light scattering ⁎ Corresponding author. E-mail address: [email protected] (C. Zhang). https://doi.org/10.1016/j.jviromet.2017.11.003 Received 18 August 2017; Received in revised form 3 November 2017; Accepted 4 November 2017 0166-0934/ © 2017 Elsevier B.V. All rights reserved.
Please cite this article as: Gillam, F., Journal of Virological Methods (2017), http://dx.doi.org/10.1016/j.jviromet.2017.11.003
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administrations in an effort to elicit the strongest mucosal immune response possible.
be the major immunodominant region (MIR) of the protein (Karpenko et al., 2000; Schodel et al., 1992). Other tags, such as histidine tags have successfully been inserted at both the N-terminus and the C-terminus of the protein without adverse effects on the assembly of the virus-like particle (VLP) (Wizemann and von Brunn, 1999; Yap et al., 2010; Yap et al., 2009; Murthy et al., 2015). A vaccination strategy against PEDV should induce a strong immune response toward the disease with a focus on mucosal stimulation in order to provide the lactogenic immunity needed. Although Cholera Toxin (CT) is generally regarded as the strongest mucosal immune response generator, it has drawbacks as an adjuvant due to its toxicity. It was recently proposed that the mechanism for CT’s success as an adjuvant may lie in it’s interaction between dendritic cells (DCs) and the nod-like receptor (NLR) NOD2 (Kim et al., 2016). The NLR family and, specifically, the NOD2 receptors are B cell receptors that recognize bacteria pathogen associated patterns (PAMPS), which instigate several protein cascades to increase the immune response (Petterson et al., 2011; Nakayamada et al., 2012; Zhong et al., 2013). Murabutide is a NOD2 agonist and has been shown to enhance the immunogenicity of HBsAg, a protein closely related to HBcAg (Audibert et al., 1984). It has also been shown to enhance the immunogenicity of the Norwalk Virus VLP, in an intranasal administration of a vaccine candidate (Jackson and Herbst-Kralovetz, 2012). CpG class C motifs are bacterial DNA motifs that are known to interact with the toll like receptor 9 (TLR9) to induce Th1 cell type switching and increase antibody (Ab) production in both humans and mice (Wang et al., 2015; Zaman et al., 2013). CpGs have been used in intranasal administrations at high concentrations without any toxic effects on mice (Kodama et al., 2006; McCluskie and Davis, 2000; Gallichan et al., 2001). Ideally, the inclusion of both CpG ODN and murabutide in a vaccine’s formulation should allow it to have the same or similar mucosal immune response as CT. Several peptide sequences have been previously identified as fairly conserved B-cell epitopes in PEDV. There are four of these epitopes located in the spike (S) protein of the virus, though only three of them are short linear peptides (Song and Park, 2012). These peptide sequences are 744YSNIGVCK752, 756SQYGQVKI771, and 1371GPRLQPY1377, hereby designated in this publication as S1, S2, and S3 respectively (Cruz et al., 2008; Sun et al., 2008). A conserved linear B-cell epitope was also identified in the membrane (M) protein of the virus (195WAFYVR200), designated as M in this publication (Zhang et al., 2012). These four sequences were used in the genetic engineering of a subunit vaccine candidate in an effort to create a more universal vaccination strategy against PEDV. In this study, five vaccine candidates (Fig. 1) using the HBcAg protein as a backbone were produced and tested in vivo. These vaccine candidates were delivered via both intranasal and intraperitoneal
2. Materials and methods 2.1. Plasmid construction DNA fragments (IDT, Coralville, IA) coding an optimized sequence for the truncated HBcAg with the inserts outlined above were amplified using PCR with primers that added the Nhe I and Hind III cut sites to the 5′ and 3′ ends, respectively (Grote et al., 2005). The amplified fragments as well as the vector plasmid pET28a (+) (Novagen, Madison, WI) were digested using the Nhe I and Hind III restriction enzymes according to vendor instructions (NEB, Ipswitch, MA) (Duan et al., 2009; Hu et al., 2011). A 5:1 stoichiometric ratio of plasmid to fragment was ligated using T4 DNA ligase according to vendor instructions (NEB). The subsequent plasmid DNA was transformed into T7 Express BL21(DE3) E. coli cells (NEB) using the heat shock method. 2.2. Expression Overnight starter cultures were used to inoculate 1 L batches of 2×YT media supplemented with 30 μg/mL kanamycin at 0.2% v/v. The E. coli cultures were allowed to incubate in a shaker at 37 °C at 200 RPM until the OD600 reached 0.7 AU. 1 mM Isopropyl β-D-1-thiogalactopyranoside (IPTG) was used to induce protein production, which was allowed to incubate for an additional 6 h. Two of the constructs: pHBcAgS2 and pHBcAgM1 would not overexpress under these conditions. Therefore, these proteins were expressed at 28 °C overnight using 1 mM IPTG after reaching an OD600 of 0.7 AU. All resultant cultures were centrifuged at 8000×g for 10 min to collect the cell pellets. Cell pellets were immediately frozen until purification. 2.3. Purification Cell pellets were re-suspended in lysis buffer (20 mM NaH2PO4, 500 mM NaCl, 10 mM Imidazole, and 2% Triton X-100 at pH 7.8) at a 1:10 w/w ratio. Cell disruption was performed on ice using a Sonic Dismembrator Model 500 (Fisher Scientific, Pittsburgh, PA), with 60 cycles of 7 s on/5 s off. The amplitude for sonication was set at 30%. The lysate was then centrifuged at 10,000g for 10 min to separate the insoluble and soluble portions. Except for ΔHBcAg, the proteins were located in the insoluble portion of the cell lysate. Inclusion bodies (IBs) were washed one time with cell lysis buffer and centrifuged again at 10,000g for 10 min. The IBs were solubilized using a 1:1 v/v of solubilization buffer (20 mM NaH2PO4, 500 mM NaCl, 10 mM Imidazole, and 0.9% Sarkosyl at pH 7.8) and allowed to mix overnight at room temperature (Tao et al., 2010). Solubilized IBs were then centrifuged at 10,000g for 10 min, and the supernatant was kept. Lysates (soluble for ΔHBcAg protein, insoluble for chimeric proteins) containing the proteins of interest (POIs) were treated with 15% w/w ammonium sulfate for a total final concentration of 1.14 M ammonium sulfate. The reaction was allowed to incubate for at least 2 h with mixing at room temperature. The precipitates were then centrifuged at 10,000g for 10 min. All POIs were found in the solid portion of the reaction. All precipitated proteins were then re-dissolved in a 1:1 v/v ratio of solubilization buffer. Immobilized metal affinity chromatography (IMAC) was performed using IMAC 6 Sepharose Fast Flow (GE Healthcare, Marlborough, MA) resin. The column was rinsed with 5 column volumes (CVs) of water, followed by 2 CVs of 200 mM NiSO4 solution to charge the resin with Ni2+ ions. The column was again flushed with 5 CVs of water and equilibrated with 5 CVs of solubilization buffer. Sample was loaded onto the column at 2 mg protein per mL of resin. Loading was followed by another 7 CVs wash with solubilization buffer. Finally, an isocratic
Fig. 1. Each vaccine candidate is based off of the ΔHBcAg protein. Foreign epitopes have been inserted into the major immunodominant region (MIR) in each case after AA79. Each construct was named as follows: (A) ΔHBcAg, (B) HBcAg + S1, (C) HBcAg + S2), (D) HBcAg + S3, (E) HBcAg + M, (F) HBcAg + S1S2S3 M.
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samples, but with a Precision Plus WesternC protein ladder (Bio-Rad). NuPAGE™ 4–12% Bis-Tris PAGE gels (Invitrogen) were blotted using a Transblot® Turbo™ instrument (Bio-Rad) onto nitrocellulose membranes. The membranes were then blocked using 5% non-fat dry milk in Tris-Buffered Saline with 0.05% Tween 20 (TBST). Membranes were rinsed three times in TBST for 5 min each and treated with primary Ab solution containing a 1:15,000 dilution of mouse anti-his tag Ab in blocking buffer for 1 h. The membrane was subsequently washed three times with TBST and treated with a secondary Ab solution containing 1:12,000 of HRP conjugated goat anti-mouse Ab (Millipore, Billerica, MA) and HRP conjugated anti-strep (Bio-Rad) for sample and ladder chemiluminescence, respectively. A final three rinses with TBST were performed followed by detection using Clarity® ECL substrate (BioRad).
step elution was performed with IMAC elution buffer (20 mM NaH2PO4, 500 mM NaCl, 300 mM Imidazole, and 0.9% Sarkosyl at pH 7.8). Following IMAC purification, step-wise dialysis was performed in PBS (137 mM NaCl, 2.7 mM KCl, 10 mM Na2HPO4, and 1.8 mM KH2PO4 at pH 7.8) at pH 7.8 with various concentrations of sarkosyl. Each dialysis step was performed using Spectralpor® dialysis membrane tubing (Spectrum Laboratories, Rancho Dominguez, CA) with a molecular weight cut off of 6–8 kDa. The step-wise buffer exchange contained 0.45%, 0.1% and 0% sarkosyl, respectively. The proteins were then taken through a polishing step using anion exchange chromatography (AEX) utilizing DEAE Sepharose FF resin (GE Healthcare). The resin was equilibrated using 5 CVs of PBS, followed by loading of the sample. The column was then washed with an additional 5 CVs of PBS. Elution was carried out using AEX elution buffer (20 mM NaH2PO4, 1 M NaCl at pH 8.2).
2.8. Endotoxin testing 2.4. Formulation A Pierce® LAL Chromogenic Endotoxin Quantitation Kit (Thermo Scientific) was used to test levels of endotoxins according to manufacturer’s instructions. Each purification process was tested for endotoxin levels after the AEX chromatography step.
Formulation was performed within two days of each inoculation using Spin X UF desalting tubes with a molecular weight cut off (MWCO) of 5 kDa (Corning, Corning, NY). In each case, the VLPs were concentrated to > 0.526 mg/mL, then diafiltered with PBS. Samples were sterile filtered through 30 mm, 0.10 μm sterile syringe filters (Celltreat, Pepperell, MA) and diluted to the desired concentration with sterile PBS. Each protein sample was formulated with 10 μL of Murabutide and 2 μL of CpG ODN at a concentration of 10 mg/mL and 5 mg/mL respectively. All vaccines were then diluted to their final volumes to result in a 1 mL dose for IP administration and a 50 μL dose for IN administration. Final vaccines should have a total of 20 μg protein, 100 μg murabutide, and 20 μg of CpG ODN. Two additional formulations were performed using the same ΔHBcAg and HBcAg + S1S2S3 M materials without the addition of the adjuvants. All candidates were then held at 4 °C (Tan et al., 2003).
2.9. Animals
Transmission electron microscopy (TEM) was performed on pure protein samples at a concentration of 0.2 mg/mL. Samples were allowed to set on formvar coated copper grids for a few seconds until the sample was blotted with filter paper. The samples were then stained with 2% phosphotungstic acid at pH 7, again for a few seconds before the stain was blotted with filter paper (Barreto-Vieira and Barth, 2015). The resulting sample was then viewed using a JEM-1400 (JEOL, Peabody, MA) electron microscope at 200,000× magnification.
Seven-week old germ free balb/c mice (Charles River) were used to determine the immunogenicity of the vaccine candidates. Each treatment group consisted of 8 mice total. Mice were acclimated for 6 days prior to a Day −1 blood draw using the submandibular collection method. Additional blood samples were collected on days 13, 27, and 42, when the mice were sacrificed via exsanguination. Fresh fecal samples were collected during each blood draw on days −1, 13, 27 and 42. Intranasal and intraperitoneal vaccinations were given on days 0, 14, and 28. Mice were weighed on a regular basis to determine overall health, with a 15% weight-loss as the cut off weight for removal from the study. Blood samples were kept at 4 °C for 1 h prior to centrifugation. Serum was collected and frozen at −20 °C until ready for testing (Pinsky et al., 2003). Fecal pellets were collected and suspended at 1:10 w/v in Superblock™ PBS based buffer containing a proprietary blocking protein and the antimicrobial agent Kathon® (Nygren et al., 2009; Nygren et al., 2008). The sample was vortexed until solids appeared to be resuspended, and then the samples were centrifuged at 10,000g for 10 min to eliminate solids. Samples were then frozen at −20 °C until testing.
2.6. Protein detection
2.10. ELISA
Protein samples were prepared for gel loading by dilution using 18 MΩ water with appropriate amounts of NuPAGE Reducing Agent (10×) (Invitrogen, Carlsbad, CA) and NuPAGE LDS Buffer (4×) (Invitrogen) to a total loading volume of 10 μL per well. Each dilution was held at 80 °C for 20 min before being cooled to 4 °C. Samples were loaded onto NuPAGE™ 4–12% Bis-Tris PAGE gels (Invitrogen) along with a PrecisionPlus™ protein ladder (Bio-Rad, Hercules, CA) and run at 200 V for 35 min. Gels were washed with 18 MΩ water three times for five minutes each and stained with SimplyBlue™ Safestain (Invitrogen) for one hour prior to an overnight rinse in 18 MΩ water. Gels were imaged using a Chemidoc XR Imager (Bio-Rad). Densitometry measurements for protein purity were done using Image Lab software (Bio-Rad). A bicinchoninic acid (BCA) assay (Thermofisher, Waltham, MA) was performed for total protein measurements by manufacturer’s instructions.
ELISA detection of individual peptides was performed using newly created proteins containing each peptide insert at the C-terminus. These proteins, referred to as ELISA fusion proteins (EFPs), contain a polystyrene (PS) binding tag RAFIASRRIRRP on the N-terminus of glutathione-S-transferase (GST) (Kumada et al., 2009). The GST protein is followed by a series of glycine and serine residues for flexibility. At the C-terminal end of each EFP, PEDV epitope peptides were attached genetically. Each protein (EFP-S1, EFP-S2, EFP-S3, EFP-M) was expressed and purified using a Glutathione Sepharose 4 B resin (GE Healthcare). The final result was high concentrations of pure proteins containing a freely available and customizable peptide region. For this study, the attached peptides coded for B-cell epitopes to PEDV. Each purified protein was diluted to 10 μg/mL in coating buffer (50 mM Na2CO3, 50 mM NaHCO3, pH 9.6) for ELISA detection. For detection of antibodies to ΔHBcAg, purified and assembled VLPs were diluted to 10 μg/ mL in coating buffer. Microlon 600 flat bottom plates were filled with 100 μL of coating solution and allowed to incubate at 37 °C for > 2 h. Plates were washed 3 times each with 200 μL of water per well, and blocked overnight in
2.5. TEM
2.7. Western blot Western blot samples were prepared identically to the NuPAGE 3
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Fig. 2. Purification of each construct was performed and tested using NuPAGE gels. In each case, the lanes are ordered as follows: (1) Protein Ladder, (2) ΔHBcAg, (3) HBcAg + S1, (4) HBcAg + S2), (5) HBcAg + S3, (6) HBcAg + M, (7) HBcAg + S1S2S3 M. (A) Cell lysate samples indicated successful expression of each protein construct. (B) Elimination of impurities prior to formulation as seen by SimplyBlue™ Safestain staining. (C) A Western blot performed on cell lysates using anti-His6 x conjugated antibodies for detection.
2.11. PEDV virus neutralization (VN) test
blocking buffer. Blocking buffer for the PS binding peptides was Pierce™ Protein-Free (PBS) Blocking buffer (Thermo Fisher). ELISA assays for ΔHBcAg were blocked with PBS + 5% nonfat dry milk. Between each subsequent step, plates were washed with PBS-T three times. Serum or fecal samples were added to each well at a total volume of 100 μL of diluted sample and allowed to incubate at RT for 1 h. Plates were then washed and treated with 100 μL of secondary Ab solution at a dilution of 1:10,000 and 1:8000 in blocking buffer for goat anti-mouse IgG HRP (Millipore, Billerica, MA) and goat anti-mouse IgA unlabeled (Southern Biotech, Birmingham, AL) respectively. Plates were incubated at RT for 1 h and washed again. IgA plates were treated with a tertiary Ab solution at a 1:4000 dilution of rabbit anti-goat IgG HRP (Southern Biotech) for 1 h and washed. Finally, 100 μL of TMB One Component Microwell Substrate (SouthernBiotech) was added to each well and incubated for ≤10 min. The reaction was then stopped using 0.05% sulfuric acid, and plates were read at 450 nm using a Biotek Synergy HTX plate reader (Winooski, VT). Each ELISA plate was arranged to include negative control samples from a group of mice receiving sterile PBS injections only for absorbance comparison. For each plate, this included three minimally diluted (1:25) samples corresponding to the appropriate sample day from the PBS injected group per plate. Absorbance values from the test samples were compared to the negative control values. The inverse of the predicted dilution at which the absorbance is no longer statistically significant (average + 3 × standard deviation) from the PBS negative controls was reported as the titer. Titers are reported as the log10() of the original value calculated. Each plate also contained samples from the test groups at the −1 DPI sample point. In every case, the PBS negative control group samples had higher OD450 measurements, so they were chosen as the comparator.
A U.S. PEDV prototype strain cell culture isolate USA/IN19338/ 2013 was isolated and propagated in Vero cells (ATCC CCL-81) as previously described (Chen et al., 2014). A stock of this virus isolate at the 7th passage in cell culture with an infectious titer of 1.6 × 106 TCID50/mL was 1:400 diluted, giving rise to virus with a titer of 4 × 103 TCID50/mL, and then used for virus neutralization test in this study. Serum and fecal samples were tested for PEDV neutralizing Ab following the previously described procedures (Thomas et al., 2015). Briefly, serum and fecal samples were inactivated at 56 °C for 30 min and then 2-fold serially diluted from 1:4 to 1:512. Equal volume of PEDV isolate was mixed with the diluted serum or fecal samples and incubated for 1 h at 37 °C with 5% CO2. Each serum or fecal sample was tested in duplicate. Vero cell monolayers grown in 96-well plates were washed once with post-inoculation media (minimum essential medium supplemented with 0.3% tryptose phosphate broth, 0.02% yeast extract, and 5 μg/mL trypsin 250, 100 unit/mL penicillin, 100 μg/mL streptomycin, 0.05 mg/mL gentamicin, and 0.25 μg/mL amphotericin B). Then 100 μL of the serum-virus mixture (containing 200 TCID50 of virus) was transferred to prewashed Vero cell monolayers. After 1 h incubation at 37 °C, the cells were washed twice with post-inoculation media and incubated with 100 μL/well of such media for 48 h at 37 °C with 5% CO2. Cells were fixed with cold 80% acetone and stained with PEDV N protein-specific monoclonal Ab SD6-29 conjugated to FITC (Medgene, Brookings, South Dakota) at a 1:100 dilution for 40–60 min. The staining was examined under a fluorescent microscope. The reciprocal of the highest serum and/or fecal dilution resulting in > 90% reduction of staining as compared to the negative serum control was 4
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3.3. Intraperitoneal immune response
defined as the VN titer of the serum and/or fecal sample. A VN titer of ≥8 was considered positive.
Mice groups having received vaccinations through an IP administration were also tested for Abs specific to ΔHBcAg first. All vaccine candidates delivered by IP generated a strong Ab response to the ΔHBcAg protein. Serum IgG titers to histidine tagged ΔHBcAg increased with each booster (Fig. 4B). The mice treated with the HBcAg + S1S2S3 M candidate showed a higher IgG titer at the end of the experiment, whereas none of the other groups were found to be significantly different. Serum IgA titers to the ΔHBcAg coated plates also increased with each booster (Fig. 4D). Mice treated with ΔHBcAg, HBcAg + S1, and HBcAg + S1S2S3 M produced the highest titers. The difference in serum IgA concentration between mice treated with HBcAg + S1 and HBcAg + S1S2S3 M was not significant, but it is significant between groups treated with ΔHBcAg and HBcAg + S1S2S3 M. Fecal IgA titers to ΔHBcAg demonstrated the production of IgA antibodies secreted into the intestines, with the ΔHBcAg treated mice having the highest values (Fig. 4F). Groups treated with HBcAg + S1 and HBcAg + S1S2S3 M had similar fecal IgA titers, and were both higher than the other groups. Presence of antibodies in the feces indicated that the vaccination strategy was able to produce secretory IgA responses to the vaccine candidates, and may aid in prevention of the disease. It should be noted, however, that fecal IgA titers are not as highly correlated with intestinal secretions as serum IgA (Externest et al., 2000). Each vaccine, when delivered in an IP injection, was also able to produce antibodies specific to the inserted PEDV epitopes as seen by ELISA analysis in Fig. 5. In all cases, the immune response to each vaccine candidate was as anticipated. Only those mice treated with vaccines containing the S1 epitope showed reactivity to the EFP-S1 coated plates (Fig. 5A). The same is true for EFP-S2, EFP-S3 and EFP-M coated plates as well (Fig. 5B–D respectively). Together, these data indicate that there is very little cross-reactivity from each vaccine candidate to the other epitopes. Interestingly, the HBcAg + S1S2S3 M group demonstrated a statistically similar immune response to each individual epitope coating as compared to each corresponding individually inserted vaccine candidate. This indicates that the presence of multiple epitopes in the HBcAg + S1S2S3 M protein did not reduce the Ab response to individual epitopes despite having been administered at the same dosage. Immune responses to the inserted epitopes were also measured using a VN assay. Data in Fig. 6 indicates only the HBcAg + S1 and the HBcAg + S1S23 M vaccine candidates showed a significantly higher VN titer than the PBS negative control. It is worth noting that high doses of PEDV given to pigs have previously demonstrated a VN titer using the same assay to be around 32 (Thomas et al., 2015).
2.12. Statistics JMP® Pro 12 software (SAS, Cary, NC) was used in all statistical analysis. All samples were run in a nested experimental design using administration, peptide/protein, and group, respectively. Individual ANOVA contrasts were performed to determine statistical significance between individual groups.
3. Results 3.1. Expression and purification Expression, purification and characterization of each vaccine candidate were performed prior to in vivo testing. The overexpression of each protein was accomplished in the insoluble portion of the cell lysates requiring an extra solubilization step (Fig. 2A). The estimated molecular weight of ΔHBcAg is 18.3 kDa as seen in lane 2 of Fig. 2A, making it slightly smaller than the other proteins. Those constructs with a single insert are expected to have a molecular weight closer to 19 kDa as seen in lanes 3–6 of Fig. 2A. The fifth construct, HBcAg + S1S2S3 M is the largest protein and is expected to have a higher molecular weight near 22 kDa as seen in lane 7 of Fig. 2A. Expressions of each protein were achieved at a concentration of approximately 2 mg/mL and as approximately 60% of the total protein content as measured by BCA assay and densitometry respectively. The presence of each protein in the insoluble lysate was confirmed by Western blot analysis using antihistidine6 x Abs prior to purification (Fig. 2C). All proteins were then purified, as can be seen in Fig. 2B. One of the candidates, HBcAg + M may have a smaller molecular weight impurity as seen in lane 6 of Fig. 2B. The protein, however, is above 96% pure by densitometry analysis indicating that it is safe for in vivo experiments. Dynamic light scattering (DLS) analysis of the AEX fractions (data not shown) each showed a particle size distribution centering between 30 and 40 nm. These measurements are as predicted, indicating that the VLPs are forming. Successful refolding and assembly of the proteins was then confirmed by TEM analysis (Fig. 3). In each case, the VLPs formed by the vaccine candidates (Fig. 3B–F) emulate that of the native protein (Fig. 3A). Finally, endotoxin measurements for safety in animal trials were performed after the AEX chromatography step. The highest value measured was 3 EU/mL, which was below the acceptable value for vaccination in humans as reported previously (data not shown) (Brito and Singh, 2011).
4. Discussion 3.2. Intranasal immune response
Contemporary strategies in vaccination primarily focus on immune system identification and elimination upon exposure to the virus. This is usually done by Ab identification, where antibodies generated through vaccination can help mobilize elements of the immune system for swift elimination of pathogens. With PEDV, however, the most susceptible subjects (young piglets) have been damaged to too great of an extent during infection in the epithelia. It is therefore critical to stop the virus from entering the mesenteric epithelia, requiring virus neutralization by secreted immunoglobulins in the intestine. For suckling piglets, this requires the transfer of immunoglobulins through colostrum and milk. Although it wasn’t successful in this case, an IN administration may be preferable to help induce a virus-specific secretory IgA response in the lactating sow during the last ten days of gestation. This strategy could increase the amount of virus-specific IgA in the colostrum and milk to provide the lactogenic protection to the suckling piglet. The lack of immune response in the IN administered groups is likely due to a low contact time between the vaccine and the epithelia
ELISA analysis of serum samples was performed for ΔHBcAg first, as a measure of overall immune response. Ab titers to ΔHBcAg in the IN group showed a poor Serum IgG response as well as serum IgA and fecal IgA responses (Fig. 4A, C, E, respectively). These data indicate that the IN administration resulted in a poor overall immune response. The highest serum IgG response came from the ΔHBcAg groups as expected, but the rest of the vaccines delivered by IN demonstrated very little response (Fig. 4A). The same pattern is true in the fecal samples, where there is only a significant difference between the ΔHBcAg group and all other vaccine candidates (Fig. 4E). There was no statistical significance between any of the vaccine candidate groups for serum IgA titers to the backbone protein (Fig. 4C). This result may be due to how low the overall serum IgA titers were in the intranasally administered groups. The titers to the ΔHBcAg coated plates were low enough in the IN groups that other analysis of the serum samples was not performed. 5
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Fig. 3. Transmission electron microscopy was used to elucidate the assembly of each vaccine candidate. (A) ΔHBcAg, (B) HBcAg + S1, (C) HBcAg + S2), (D) HBcAg + S3, (E) HBcAg + M, and (F) HBcAg + S1S2S3 M.
Monoclonal antibodies (mAbs) made and purified from the injection of the spike protein from PEDV have indicated that mAbs containing high titers to portions of the protein containing the YSNIGVCK (S1) motif have a much higher virus neutralization capability than mAbs with high titers to peptide sequences containing either the SQYGQVKI (S2) or the GPRLQPY (S3) motifs (Okda et al., 2017). Though most mAbs produced in that study indicated that there was some neutralization activity, the reduced VN titers may indicate that they are less suitable targets in a subunit vaccination strategy for PEDV. The relatively high virus titers used in the VN testing during this experiment may have simply overwhelmed antibody populations with lower utility in neutralization. It is important to note that mice treated with HBcAg + S2 cannot be included in the data to support this hypothesis. The HBcAg + S2 vaccine was originally designed to have the neutralizing antibodies from the CV777 strain originally found in Denmark. However, many of the strains in the recent (2013) outbreak in the US are phylogenetically distant from the original strain when arranged based on the genome coding for the spike protein (Carvajal et al., 2015; Lee, 2015). Indeed, sequence data from Indiana based strains during the 2013 outbreak such as that used for the assay confirms that the neutralizing “S2” epitope sequence is actually 756SQSGQVKI771 instead of 756 SQYGQVKI771 as was used in the vaccine design. This oversight can be easily changed, possibly allowing for a more effective multivalent vaccine candidate. It was interesting that the HBcAg + S1S2S3 M vaccine candidate was able to neutralize the same amount of PEDV on a per dose basis as the HBcAg + S1 candidate. With four epitopes inserted into the MIR of the ΔHBcAg, it could be hypothesized that the S1 epitope would have a 1:4 chance of interaction with a B-cell receptor. Perhaps the inclusion of multiple B-cell epitopes in the MIR increases the pathogen associated molecular patterns (PAMPS) recognized by the immune system, and therefore increases the overall immunogenicity of the VLP. This phenomenon may be of use in the design of future vaccine candidates. If the
tissue. The introduction of a polymer, such as chitosan, in the formulation of the vaccines could allow the VLPs to adhere to the epithelial surface for a longer amount of time. An increase in contact time would then promote the internalization of the proteins and possibly increase the immune response (Wang et al., 2015; Smith et al., 2014). One important finding was that there was no difference in neutralizing Ab concentration between the monovalent HBcAg + S1 vaccine candidate and the multivalent HBcAg + S1S2S3 M vaccine candidate. Individual epitope titers as measured by ELISA indicated that the HBcAg + S1S2S3 M vaccine candidate was able to produce comparable specific antibody levels as the vaccine candidates containing the single epitopes. Given only the ELISA data, one might be tempted to conclude that the HBcAg + S1S2S3 M vaccine candidate could be much more effective compared to the other proteins. The ELISA data indicates that HBcAg + S1S2S3 M induced a higher overall immune response because of its ability to induce an equal epitope-specific titer in mice at the same dosage. Inclusion of multiple epitopes could also have the added benefit of providing a more diverse immune response as well, allowing possible protection from multiple strains of the virus if mutations were to occur in the epitope regions. Neutralization data, however, indicates that there is a more complicated phenomenon. A second important finding was that only two of the candidates were able to successfully neutralize virus using the assay as described. This may be due to the amount of virus that is used in the assay’s execution, or the genotype of the virus itself. It is hypothesized that Abs corresponding to the S1 epitope are better at neutralizing the virus than Abs to the other epitopes. In this experiment, each individual vaccine candidate had a significantly higher ELISA titer to the epitope insertion than the negative controls, but there was a lack of VN response in the majority of the vaccine candidates. This discrepancy may be due to something as simple as conformational changes in the neutralizing motifs based on viral genotypes (Liu et al., 2017). Another possible mechanism for prevention of neutralization may simply be efficacy. 6
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Fig. 4. Preliminary analysis of immune response was performed using an ELISA assay for antibodies to ΔHBcAg. (A) Serum IgG Titers for IN Administration, (B) Serum IgG Titers for IP Administration, (C) Serum IgA titers for IN Administration, (D) Serum IgA Titers for IP Administration, (E) Fecal IgA titers for IN Administration, and (F) Fecal IgA titers for IP Administration. Each value is compared to a PBS negative control group on each plate. Error bars represent the standard error of the measurements. (* = P ≤ 0.05, ** = P ≤ 0.01, *** = P ≤ 0.001).
and enhance the immune response to the insert (Yin et al., 2014). It may therefore be possible to modify the backbone protein, maintaining vaccine efficacy while reducing the exposed epitopes from HBcAg.
inclusion of multiple conserved B-cell epitopes raises the overall immunogenicity of the vaccine without depleting its ability to produce neutralizing antibodies, then perhaps this strategy could be employed to produce a vaccine that infers protection to both suckling piglets as well as adult pigs. One possible pitfall to using the HBcAg backbone protein might be the prevalence of swine hepatitis B virus (SHBV). Recent evidence suggests this prevalence may be as high as 25% in agricultural pigs (Li et al., 2010). However, another study has indicated that the presence of anti-HBcAg Abs in sows may be closer to 12% (Song et al., 2015). There is therefore concern that the presence of these antibodies in a pregnant sow may cause the elimination of the vaccine through previous immunity, reducing its efficacy. One possible strategy to combat this phenomenon may be through simple redesign of the vaccine. The elimination of key amino acids in the sequence of the backbone have been shown to reduce immunity to the HBcAg portion of the protein
5. Conclusions The preceding data indicate that the HBcAg VLP platform shows promise as an effective tool in a vaccine strategy toward PEDV. Neutralization of a strain of PEDV from the more recent outbreak corroborates previous identification of the YSNIGVCK motif from the Sprotein in PEDV. ELISA titers to three other B-cell epitopes indicate that though they are able to produce significant Abs, the Abs produced may have limited neutralization of high titers of virus. There seemed to be no disadvantage to the inclusion of multiple epitopes in the MIR of HBcAg on viral neutralization, indicating that the multivalent strategy might allow for an effective vaccine used for herd immunity as well as 7
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Fig. 5. ELISA was performed on samples from 42 days post inoculation with EFP proteins containing the individual epitopes as coating proteins to test the immune response to the inserted epitopes. All samples were tested for an immune response to each epitope to ensure there was no cross-reactivity. Coating peptides are as follows: (A) EFP-S1, (B) EFPS2, (C) EFP-S3, and (D) EFP-M. Each value is compared to a PBS negative control group on each plate. Error bars represent the standard error of the measurements. (* = P ≤ 0.05, ** = P ≤ 0.01, *** = P ≤ 0.001).
lactogenic protection. Acknowledgement We thank the generous financial support by Smithfield Foods and Murphy-Brown LLC and the insightful discussion with their scientists, including Drs. Terry Coffey, Perry Harms, Joe Fent, Jeremy Pittman, and Marlin Hoogland, especially Dr. Terry Coffey, throughout the project period. References Alonso, C., Goede, D.P., Morrison, R.B., Davies, P.R., Rovira, A., Marthaler, D.G., Torremorell, M., 2014. Evidence of infectivity of airborne porcine epidemic diarrhea virus and detection of airborne viral RNA at long distances from infected herds. Vet. Res. 45, 73. Audibert, F.M., Przewlocki, G., Leclerc, C., Jolivet, M., Gras-Masse, H., Tartar, A., Chedid, L., 1984. Enhancement by murabutide of the immune response to natural and synthetic hepatitis B surface antigens. Infect. Immun. 45, 261–266. Barreto-Vieira, D.F., Barth, O.M., 2015. Negative and Positive Staining in Transmission Electron Microscopy for Virus Diagnosis. Bottcher, B., Wynne, S.A., Crowther, R.A., 1997. Determination of the fold of the core protein of hepatitis B virus by electron cryomicroscopy. Nature 386, 88–91. Brito, L.A., Singh, M., 2011. Acceptable levels of endotoxin in vaccine formulations during preclinical research. J. Pharm. Sci. 100, 34–37. Carvajal, A., Argüello, H., Martínez-Lobo, F.J., Costillas, S., Miranda, R., de Nova, P.J.G., Rubio, P., 2015. Porcine epidemic diarrhoea: new insights into an old disease. Porcine Health Manage. 1, 12. Chen, Q., Li, G., Stasko, J., Thomas, J.T., Stensland, W.R., Pillatzki, A.E., Gauger, P.C., Schwartz, K.J., Madson, D., Yoon, K.-J., 2014. Isolation and characterization of porcine epidemic diarrhea viruses associated with the 2013 disease outbreak among swine in the United States. J. Clin. Microbiol. 52, 234–243. Cima, G., 2014. PED virus reinfecting US herds. Virus estimated to have killed 7 millionplus pigs. J. Am. Vet. Med. Assoc. 245, 166.
Fig. 6. A virus neutralization assay was run on samples from the 42nd day post inoculation. Error bars represent the standard error of the measurements. (* = P ≤ 0.05, ** = P ≤ 0.01, *** = P ≤ 0.001).
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Journal of Virological Methods journal homepage: www.elsevier.com/locate/jviromet
Hepatitis B core antigen based novel vaccine against porcine epidemic diarrhea virus Frank Gillama, Jianqiang Zhangb, Chenming Zhanga, a b
⁎
Department of Biological Systems Engineering, Virginia Tech, 1230 Washington St. SW, Blacksburg, VA 24061, USA Department of Veterinary Diagnostic and Production Animal Medicine, Iowa State University, Ames, IA, USA
A R T I C L E I N F O
A B S T R A C T
Keywords: HBcAg PEDV Vaccine VLP Purification
Porcine epidemic diarrhea Virus (PEDV) is the causative agent of porcine epidemic diarrhea, which is a devastating viral disease and causes severe economic loss to the swine industry. Current vaccine options for PEDV include modified live viruses and killed live viruses. Though these vaccines have shown efficacy, some have side effects including viral shedding. This report details an E. coli based expression and purification process of multiple vaccine candidates for PEDV using Hepatitis B Core Antigen (HBcAg) as a backbone protein. Short linear peptide sequences from PEDV were inserted into the immunodominant region of HBcAg in a novel recombinant vaccine design against PEDV. These peptide sequences were successfully inserted individually as well as all together in a multivalent strategy. Each vaccine candidate was tested in vivo in an intranasal as well as an intraperitoneal administration. Although each candidate was able to elicit a strong immunogenic response specific for the inserted peptide sequences, only two out of five of the test candidates demonstrated an ability to elicit an immune response capable of virus neutralization when delivered via intraperitoneal administration in mice.
1. Introduction Porcine epidemic diarrhea Virus (PEDV) is a member of the Alphacoronavirus genus in the Coronaviridae (CV) family in the Nidovirales order. The genome of PEDV is approximately 28 kb in length and incudes 5′ and 3′ untranslated regions and 7 known open reading frames (ORFs) in the order of ORF1a, ORF1b, spike (S) protein, ORF3, envelope (E) protein, membrane (M) glycoprotein, and nucleocaspid (N) protein (Song and Park, 2012). PEDV was first discovered in Europe in the 1970s and spread to Asia in the 1980s and 1990s (Song and Park, 2012; Pensaert and de Bouck, 1978). PEDV was detected for the first time in North America in 2013 and caused severe disease and substantial economic losses (Stevenson et al., 2013; Cima, 2014). The symptoms of PEDV are watery diarrhea, depression, and anorexia. The high mortality rate of PEDV in suckling piglets is caused by the destruction of susceptible microvilli in the small intestine (Madson et al., 2014). The fecal-oral route of infection has the highest rate of transmission, although evidence suggests that airborne aerosolized virus may also be infectious (Alonso et al., 2014). Even though vaccines currently exist for PEDV in killed virus (KV) and modified live virus
(MLV) formats, there are side effects from their administration. A recombinant vaccine strategy may therefore be more appropriate for PEDV in agriculture. Hepatitis B Core Antigen (HBcAg) is the nucleocapsid protein from the Hepatitis B virus. The native form of the protein is 183 amino acids (AA) in length and has the ability to self-assemble into the nucleocapsid structure with a diameter around 30 nm (Cohen and Richmond, 1982; Bottcher et al., 1997). The full protein consists of two domains, only the first of which is required for self-assembly of the protein (Wingfield et al., 1995; Tan et al., 2003). Recombinant versions of the protein typically consist of only the first 149 AA and are abbreviated as ΔHBcAg. Genetic manipulation of ΔHBcAg has been demonstrated previously in vaccine designs, some of which have been approved for use in humans in the US (Schodel et al., 1994a; Schodel et al., 1994b; Schodel et al., 1996; Yang et al., 2017). Short linear epitopes from other viruses are often inserted at AA P80, which can be done with successful self-assembly and subsequent foreign antigen presentation provided that the peptide insertion does not cause sever steric hindrance through secondary or tertiary structure. This location within the protein has been shown to induce the highest immune response and is considered to
Abbreviations: PEDV, porcine epidemic diarrhea virus; EFP, ELISA fusion protein; Ab, antibody; HBcAg, hepatitis B Core antigen; VLP, virus like particle; VN, virus neutralization; PS, polystyrene; GST, glutathione-S-transferase; AEX, anion exchange; IMAC, immobilized metal affinity chromatography; IPTG, isopropyl β-D-1-thiogalactopyranoside; DLS, dynamic light scattering ⁎ Corresponding author. E-mail address: [email protected] (C. Zhang). https://doi.org/10.1016/j.jviromet.2017.11.003 Received 18 August 2017; Received in revised form 3 November 2017; Accepted 4 November 2017 0166-0934/ © 2017 Elsevier B.V. All rights reserved.
Please cite this article as: Gillam, F., Journal of Virological Methods (2017), http://dx.doi.org/10.1016/j.jviromet.2017.11.003
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administrations in an effort to elicit the strongest mucosal immune response possible.
be the major immunodominant region (MIR) of the protein (Karpenko et al., 2000; Schodel et al., 1992). Other tags, such as histidine tags have successfully been inserted at both the N-terminus and the C-terminus of the protein without adverse effects on the assembly of the virus-like particle (VLP) (Wizemann and von Brunn, 1999; Yap et al., 2010; Yap et al., 2009; Murthy et al., 2015). A vaccination strategy against PEDV should induce a strong immune response toward the disease with a focus on mucosal stimulation in order to provide the lactogenic immunity needed. Although Cholera Toxin (CT) is generally regarded as the strongest mucosal immune response generator, it has drawbacks as an adjuvant due to its toxicity. It was recently proposed that the mechanism for CT’s success as an adjuvant may lie in it’s interaction between dendritic cells (DCs) and the nod-like receptor (NLR) NOD2 (Kim et al., 2016). The NLR family and, specifically, the NOD2 receptors are B cell receptors that recognize bacteria pathogen associated patterns (PAMPS), which instigate several protein cascades to increase the immune response (Petterson et al., 2011; Nakayamada et al., 2012; Zhong et al., 2013). Murabutide is a NOD2 agonist and has been shown to enhance the immunogenicity of HBsAg, a protein closely related to HBcAg (Audibert et al., 1984). It has also been shown to enhance the immunogenicity of the Norwalk Virus VLP, in an intranasal administration of a vaccine candidate (Jackson and Herbst-Kralovetz, 2012). CpG class C motifs are bacterial DNA motifs that are known to interact with the toll like receptor 9 (TLR9) to induce Th1 cell type switching and increase antibody (Ab) production in both humans and mice (Wang et al., 2015; Zaman et al., 2013). CpGs have been used in intranasal administrations at high concentrations without any toxic effects on mice (Kodama et al., 2006; McCluskie and Davis, 2000; Gallichan et al., 2001). Ideally, the inclusion of both CpG ODN and murabutide in a vaccine’s formulation should allow it to have the same or similar mucosal immune response as CT. Several peptide sequences have been previously identified as fairly conserved B-cell epitopes in PEDV. There are four of these epitopes located in the spike (S) protein of the virus, though only three of them are short linear peptides (Song and Park, 2012). These peptide sequences are 744YSNIGVCK752, 756SQYGQVKI771, and 1371GPRLQPY1377, hereby designated in this publication as S1, S2, and S3 respectively (Cruz et al., 2008; Sun et al., 2008). A conserved linear B-cell epitope was also identified in the membrane (M) protein of the virus (195WAFYVR200), designated as M in this publication (Zhang et al., 2012). These four sequences were used in the genetic engineering of a subunit vaccine candidate in an effort to create a more universal vaccination strategy against PEDV. In this study, five vaccine candidates (Fig. 1) using the HBcAg protein as a backbone were produced and tested in vivo. These vaccine candidates were delivered via both intranasal and intraperitoneal
2. Materials and methods 2.1. Plasmid construction DNA fragments (IDT, Coralville, IA) coding an optimized sequence for the truncated HBcAg with the inserts outlined above were amplified using PCR with primers that added the Nhe I and Hind III cut sites to the 5′ and 3′ ends, respectively (Grote et al., 2005). The amplified fragments as well as the vector plasmid pET28a (+) (Novagen, Madison, WI) were digested using the Nhe I and Hind III restriction enzymes according to vendor instructions (NEB, Ipswitch, MA) (Duan et al., 2009; Hu et al., 2011). A 5:1 stoichiometric ratio of plasmid to fragment was ligated using T4 DNA ligase according to vendor instructions (NEB). The subsequent plasmid DNA was transformed into T7 Express BL21(DE3) E. coli cells (NEB) using the heat shock method. 2.2. Expression Overnight starter cultures were used to inoculate 1 L batches of 2×YT media supplemented with 30 μg/mL kanamycin at 0.2% v/v. The E. coli cultures were allowed to incubate in a shaker at 37 °C at 200 RPM until the OD600 reached 0.7 AU. 1 mM Isopropyl β-D-1-thiogalactopyranoside (IPTG) was used to induce protein production, which was allowed to incubate for an additional 6 h. Two of the constructs: pHBcAgS2 and pHBcAgM1 would not overexpress under these conditions. Therefore, these proteins were expressed at 28 °C overnight using 1 mM IPTG after reaching an OD600 of 0.7 AU. All resultant cultures were centrifuged at 8000×g for 10 min to collect the cell pellets. Cell pellets were immediately frozen until purification. 2.3. Purification Cell pellets were re-suspended in lysis buffer (20 mM NaH2PO4, 500 mM NaCl, 10 mM Imidazole, and 2% Triton X-100 at pH 7.8) at a 1:10 w/w ratio. Cell disruption was performed on ice using a Sonic Dismembrator Model 500 (Fisher Scientific, Pittsburgh, PA), with 60 cycles of 7 s on/5 s off. The amplitude for sonication was set at 30%. The lysate was then centrifuged at 10,000g for 10 min to separate the insoluble and soluble portions. Except for ΔHBcAg, the proteins were located in the insoluble portion of the cell lysate. Inclusion bodies (IBs) were washed one time with cell lysis buffer and centrifuged again at 10,000g for 10 min. The IBs were solubilized using a 1:1 v/v of solubilization buffer (20 mM NaH2PO4, 500 mM NaCl, 10 mM Imidazole, and 0.9% Sarkosyl at pH 7.8) and allowed to mix overnight at room temperature (Tao et al., 2010). Solubilized IBs were then centrifuged at 10,000g for 10 min, and the supernatant was kept. Lysates (soluble for ΔHBcAg protein, insoluble for chimeric proteins) containing the proteins of interest (POIs) were treated with 15% w/w ammonium sulfate for a total final concentration of 1.14 M ammonium sulfate. The reaction was allowed to incubate for at least 2 h with mixing at room temperature. The precipitates were then centrifuged at 10,000g for 10 min. All POIs were found in the solid portion of the reaction. All precipitated proteins were then re-dissolved in a 1:1 v/v ratio of solubilization buffer. Immobilized metal affinity chromatography (IMAC) was performed using IMAC 6 Sepharose Fast Flow (GE Healthcare, Marlborough, MA) resin. The column was rinsed with 5 column volumes (CVs) of water, followed by 2 CVs of 200 mM NiSO4 solution to charge the resin with Ni2+ ions. The column was again flushed with 5 CVs of water and equilibrated with 5 CVs of solubilization buffer. Sample was loaded onto the column at 2 mg protein per mL of resin. Loading was followed by another 7 CVs wash with solubilization buffer. Finally, an isocratic
Fig. 1. Each vaccine candidate is based off of the ΔHBcAg protein. Foreign epitopes have been inserted into the major immunodominant region (MIR) in each case after AA79. Each construct was named as follows: (A) ΔHBcAg, (B) HBcAg + S1, (C) HBcAg + S2), (D) HBcAg + S3, (E) HBcAg + M, (F) HBcAg + S1S2S3 M.
2
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samples, but with a Precision Plus WesternC protein ladder (Bio-Rad). NuPAGE™ 4–12% Bis-Tris PAGE gels (Invitrogen) were blotted using a Transblot® Turbo™ instrument (Bio-Rad) onto nitrocellulose membranes. The membranes were then blocked using 5% non-fat dry milk in Tris-Buffered Saline with 0.05% Tween 20 (TBST). Membranes were rinsed three times in TBST for 5 min each and treated with primary Ab solution containing a 1:15,000 dilution of mouse anti-his tag Ab in blocking buffer for 1 h. The membrane was subsequently washed three times with TBST and treated with a secondary Ab solution containing 1:12,000 of HRP conjugated goat anti-mouse Ab (Millipore, Billerica, MA) and HRP conjugated anti-strep (Bio-Rad) for sample and ladder chemiluminescence, respectively. A final three rinses with TBST were performed followed by detection using Clarity® ECL substrate (BioRad).
step elution was performed with IMAC elution buffer (20 mM NaH2PO4, 500 mM NaCl, 300 mM Imidazole, and 0.9% Sarkosyl at pH 7.8). Following IMAC purification, step-wise dialysis was performed in PBS (137 mM NaCl, 2.7 mM KCl, 10 mM Na2HPO4, and 1.8 mM KH2PO4 at pH 7.8) at pH 7.8 with various concentrations of sarkosyl. Each dialysis step was performed using Spectralpor® dialysis membrane tubing (Spectrum Laboratories, Rancho Dominguez, CA) with a molecular weight cut off of 6–8 kDa. The step-wise buffer exchange contained 0.45%, 0.1% and 0% sarkosyl, respectively. The proteins were then taken through a polishing step using anion exchange chromatography (AEX) utilizing DEAE Sepharose FF resin (GE Healthcare). The resin was equilibrated using 5 CVs of PBS, followed by loading of the sample. The column was then washed with an additional 5 CVs of PBS. Elution was carried out using AEX elution buffer (20 mM NaH2PO4, 1 M NaCl at pH 8.2).
2.8. Endotoxin testing 2.4. Formulation A Pierce® LAL Chromogenic Endotoxin Quantitation Kit (Thermo Scientific) was used to test levels of endotoxins according to manufacturer’s instructions. Each purification process was tested for endotoxin levels after the AEX chromatography step.
Formulation was performed within two days of each inoculation using Spin X UF desalting tubes with a molecular weight cut off (MWCO) of 5 kDa (Corning, Corning, NY). In each case, the VLPs were concentrated to > 0.526 mg/mL, then diafiltered with PBS. Samples were sterile filtered through 30 mm, 0.10 μm sterile syringe filters (Celltreat, Pepperell, MA) and diluted to the desired concentration with sterile PBS. Each protein sample was formulated with 10 μL of Murabutide and 2 μL of CpG ODN at a concentration of 10 mg/mL and 5 mg/mL respectively. All vaccines were then diluted to their final volumes to result in a 1 mL dose for IP administration and a 50 μL dose for IN administration. Final vaccines should have a total of 20 μg protein, 100 μg murabutide, and 20 μg of CpG ODN. Two additional formulations were performed using the same ΔHBcAg and HBcAg + S1S2S3 M materials without the addition of the adjuvants. All candidates were then held at 4 °C (Tan et al., 2003).
2.9. Animals
Transmission electron microscopy (TEM) was performed on pure protein samples at a concentration of 0.2 mg/mL. Samples were allowed to set on formvar coated copper grids for a few seconds until the sample was blotted with filter paper. The samples were then stained with 2% phosphotungstic acid at pH 7, again for a few seconds before the stain was blotted with filter paper (Barreto-Vieira and Barth, 2015). The resulting sample was then viewed using a JEM-1400 (JEOL, Peabody, MA) electron microscope at 200,000× magnification.
Seven-week old germ free balb/c mice (Charles River) were used to determine the immunogenicity of the vaccine candidates. Each treatment group consisted of 8 mice total. Mice were acclimated for 6 days prior to a Day −1 blood draw using the submandibular collection method. Additional blood samples were collected on days 13, 27, and 42, when the mice were sacrificed via exsanguination. Fresh fecal samples were collected during each blood draw on days −1, 13, 27 and 42. Intranasal and intraperitoneal vaccinations were given on days 0, 14, and 28. Mice were weighed on a regular basis to determine overall health, with a 15% weight-loss as the cut off weight for removal from the study. Blood samples were kept at 4 °C for 1 h prior to centrifugation. Serum was collected and frozen at −20 °C until ready for testing (Pinsky et al., 2003). Fecal pellets were collected and suspended at 1:10 w/v in Superblock™ PBS based buffer containing a proprietary blocking protein and the antimicrobial agent Kathon® (Nygren et al., 2009; Nygren et al., 2008). The sample was vortexed until solids appeared to be resuspended, and then the samples were centrifuged at 10,000g for 10 min to eliminate solids. Samples were then frozen at −20 °C until testing.
2.6. Protein detection
2.10. ELISA
Protein samples were prepared for gel loading by dilution using 18 MΩ water with appropriate amounts of NuPAGE Reducing Agent (10×) (Invitrogen, Carlsbad, CA) and NuPAGE LDS Buffer (4×) (Invitrogen) to a total loading volume of 10 μL per well. Each dilution was held at 80 °C for 20 min before being cooled to 4 °C. Samples were loaded onto NuPAGE™ 4–12% Bis-Tris PAGE gels (Invitrogen) along with a PrecisionPlus™ protein ladder (Bio-Rad, Hercules, CA) and run at 200 V for 35 min. Gels were washed with 18 MΩ water three times for five minutes each and stained with SimplyBlue™ Safestain (Invitrogen) for one hour prior to an overnight rinse in 18 MΩ water. Gels were imaged using a Chemidoc XR Imager (Bio-Rad). Densitometry measurements for protein purity were done using Image Lab software (Bio-Rad). A bicinchoninic acid (BCA) assay (Thermofisher, Waltham, MA) was performed for total protein measurements by manufacturer’s instructions.
ELISA detection of individual peptides was performed using newly created proteins containing each peptide insert at the C-terminus. These proteins, referred to as ELISA fusion proteins (EFPs), contain a polystyrene (PS) binding tag RAFIASRRIRRP on the N-terminus of glutathione-S-transferase (GST) (Kumada et al., 2009). The GST protein is followed by a series of glycine and serine residues for flexibility. At the C-terminal end of each EFP, PEDV epitope peptides were attached genetically. Each protein (EFP-S1, EFP-S2, EFP-S3, EFP-M) was expressed and purified using a Glutathione Sepharose 4 B resin (GE Healthcare). The final result was high concentrations of pure proteins containing a freely available and customizable peptide region. For this study, the attached peptides coded for B-cell epitopes to PEDV. Each purified protein was diluted to 10 μg/mL in coating buffer (50 mM Na2CO3, 50 mM NaHCO3, pH 9.6) for ELISA detection. For detection of antibodies to ΔHBcAg, purified and assembled VLPs were diluted to 10 μg/ mL in coating buffer. Microlon 600 flat bottom plates were filled with 100 μL of coating solution and allowed to incubate at 37 °C for > 2 h. Plates were washed 3 times each with 200 μL of water per well, and blocked overnight in
2.5. TEM
2.7. Western blot Western blot samples were prepared identically to the NuPAGE 3
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Fig. 2. Purification of each construct was performed and tested using NuPAGE gels. In each case, the lanes are ordered as follows: (1) Protein Ladder, (2) ΔHBcAg, (3) HBcAg + S1, (4) HBcAg + S2), (5) HBcAg + S3, (6) HBcAg + M, (7) HBcAg + S1S2S3 M. (A) Cell lysate samples indicated successful expression of each protein construct. (B) Elimination of impurities prior to formulation as seen by SimplyBlue™ Safestain staining. (C) A Western blot performed on cell lysates using anti-His6 x conjugated antibodies for detection.
2.11. PEDV virus neutralization (VN) test
blocking buffer. Blocking buffer for the PS binding peptides was Pierce™ Protein-Free (PBS) Blocking buffer (Thermo Fisher). ELISA assays for ΔHBcAg were blocked with PBS + 5% nonfat dry milk. Between each subsequent step, plates were washed with PBS-T three times. Serum or fecal samples were added to each well at a total volume of 100 μL of diluted sample and allowed to incubate at RT for 1 h. Plates were then washed and treated with 100 μL of secondary Ab solution at a dilution of 1:10,000 and 1:8000 in blocking buffer for goat anti-mouse IgG HRP (Millipore, Billerica, MA) and goat anti-mouse IgA unlabeled (Southern Biotech, Birmingham, AL) respectively. Plates were incubated at RT for 1 h and washed again. IgA plates were treated with a tertiary Ab solution at a 1:4000 dilution of rabbit anti-goat IgG HRP (Southern Biotech) for 1 h and washed. Finally, 100 μL of TMB One Component Microwell Substrate (SouthernBiotech) was added to each well and incubated for ≤10 min. The reaction was then stopped using 0.05% sulfuric acid, and plates were read at 450 nm using a Biotek Synergy HTX plate reader (Winooski, VT). Each ELISA plate was arranged to include negative control samples from a group of mice receiving sterile PBS injections only for absorbance comparison. For each plate, this included three minimally diluted (1:25) samples corresponding to the appropriate sample day from the PBS injected group per plate. Absorbance values from the test samples were compared to the negative control values. The inverse of the predicted dilution at which the absorbance is no longer statistically significant (average + 3 × standard deviation) from the PBS negative controls was reported as the titer. Titers are reported as the log10() of the original value calculated. Each plate also contained samples from the test groups at the −1 DPI sample point. In every case, the PBS negative control group samples had higher OD450 measurements, so they were chosen as the comparator.
A U.S. PEDV prototype strain cell culture isolate USA/IN19338/ 2013 was isolated and propagated in Vero cells (ATCC CCL-81) as previously described (Chen et al., 2014). A stock of this virus isolate at the 7th passage in cell culture with an infectious titer of 1.6 × 106 TCID50/mL was 1:400 diluted, giving rise to virus with a titer of 4 × 103 TCID50/mL, and then used for virus neutralization test in this study. Serum and fecal samples were tested for PEDV neutralizing Ab following the previously described procedures (Thomas et al., 2015). Briefly, serum and fecal samples were inactivated at 56 °C for 30 min and then 2-fold serially diluted from 1:4 to 1:512. Equal volume of PEDV isolate was mixed with the diluted serum or fecal samples and incubated for 1 h at 37 °C with 5% CO2. Each serum or fecal sample was tested in duplicate. Vero cell monolayers grown in 96-well plates were washed once with post-inoculation media (minimum essential medium supplemented with 0.3% tryptose phosphate broth, 0.02% yeast extract, and 5 μg/mL trypsin 250, 100 unit/mL penicillin, 100 μg/mL streptomycin, 0.05 mg/mL gentamicin, and 0.25 μg/mL amphotericin B). Then 100 μL of the serum-virus mixture (containing 200 TCID50 of virus) was transferred to prewashed Vero cell monolayers. After 1 h incubation at 37 °C, the cells were washed twice with post-inoculation media and incubated with 100 μL/well of such media for 48 h at 37 °C with 5% CO2. Cells were fixed with cold 80% acetone and stained with PEDV N protein-specific monoclonal Ab SD6-29 conjugated to FITC (Medgene, Brookings, South Dakota) at a 1:100 dilution for 40–60 min. The staining was examined under a fluorescent microscope. The reciprocal of the highest serum and/or fecal dilution resulting in > 90% reduction of staining as compared to the negative serum control was 4
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3.3. Intraperitoneal immune response
defined as the VN titer of the serum and/or fecal sample. A VN titer of ≥8 was considered positive.
Mice groups having received vaccinations through an IP administration were also tested for Abs specific to ΔHBcAg first. All vaccine candidates delivered by IP generated a strong Ab response to the ΔHBcAg protein. Serum IgG titers to histidine tagged ΔHBcAg increased with each booster (Fig. 4B). The mice treated with the HBcAg + S1S2S3 M candidate showed a higher IgG titer at the end of the experiment, whereas none of the other groups were found to be significantly different. Serum IgA titers to the ΔHBcAg coated plates also increased with each booster (Fig. 4D). Mice treated with ΔHBcAg, HBcAg + S1, and HBcAg + S1S2S3 M produced the highest titers. The difference in serum IgA concentration between mice treated with HBcAg + S1 and HBcAg + S1S2S3 M was not significant, but it is significant between groups treated with ΔHBcAg and HBcAg + S1S2S3 M. Fecal IgA titers to ΔHBcAg demonstrated the production of IgA antibodies secreted into the intestines, with the ΔHBcAg treated mice having the highest values (Fig. 4F). Groups treated with HBcAg + S1 and HBcAg + S1S2S3 M had similar fecal IgA titers, and were both higher than the other groups. Presence of antibodies in the feces indicated that the vaccination strategy was able to produce secretory IgA responses to the vaccine candidates, and may aid in prevention of the disease. It should be noted, however, that fecal IgA titers are not as highly correlated with intestinal secretions as serum IgA (Externest et al., 2000). Each vaccine, when delivered in an IP injection, was also able to produce antibodies specific to the inserted PEDV epitopes as seen by ELISA analysis in Fig. 5. In all cases, the immune response to each vaccine candidate was as anticipated. Only those mice treated with vaccines containing the S1 epitope showed reactivity to the EFP-S1 coated plates (Fig. 5A). The same is true for EFP-S2, EFP-S3 and EFP-M coated plates as well (Fig. 5B–D respectively). Together, these data indicate that there is very little cross-reactivity from each vaccine candidate to the other epitopes. Interestingly, the HBcAg + S1S2S3 M group demonstrated a statistically similar immune response to each individual epitope coating as compared to each corresponding individually inserted vaccine candidate. This indicates that the presence of multiple epitopes in the HBcAg + S1S2S3 M protein did not reduce the Ab response to individual epitopes despite having been administered at the same dosage. Immune responses to the inserted epitopes were also measured using a VN assay. Data in Fig. 6 indicates only the HBcAg + S1 and the HBcAg + S1S23 M vaccine candidates showed a significantly higher VN titer than the PBS negative control. It is worth noting that high doses of PEDV given to pigs have previously demonstrated a VN titer using the same assay to be around 32 (Thomas et al., 2015).
2.12. Statistics JMP® Pro 12 software (SAS, Cary, NC) was used in all statistical analysis. All samples were run in a nested experimental design using administration, peptide/protein, and group, respectively. Individual ANOVA contrasts were performed to determine statistical significance between individual groups.
3. Results 3.1. Expression and purification Expression, purification and characterization of each vaccine candidate were performed prior to in vivo testing. The overexpression of each protein was accomplished in the insoluble portion of the cell lysates requiring an extra solubilization step (Fig. 2A). The estimated molecular weight of ΔHBcAg is 18.3 kDa as seen in lane 2 of Fig. 2A, making it slightly smaller than the other proteins. Those constructs with a single insert are expected to have a molecular weight closer to 19 kDa as seen in lanes 3–6 of Fig. 2A. The fifth construct, HBcAg + S1S2S3 M is the largest protein and is expected to have a higher molecular weight near 22 kDa as seen in lane 7 of Fig. 2A. Expressions of each protein were achieved at a concentration of approximately 2 mg/mL and as approximately 60% of the total protein content as measured by BCA assay and densitometry respectively. The presence of each protein in the insoluble lysate was confirmed by Western blot analysis using antihistidine6 x Abs prior to purification (Fig. 2C). All proteins were then purified, as can be seen in Fig. 2B. One of the candidates, HBcAg + M may have a smaller molecular weight impurity as seen in lane 6 of Fig. 2B. The protein, however, is above 96% pure by densitometry analysis indicating that it is safe for in vivo experiments. Dynamic light scattering (DLS) analysis of the AEX fractions (data not shown) each showed a particle size distribution centering between 30 and 40 nm. These measurements are as predicted, indicating that the VLPs are forming. Successful refolding and assembly of the proteins was then confirmed by TEM analysis (Fig. 3). In each case, the VLPs formed by the vaccine candidates (Fig. 3B–F) emulate that of the native protein (Fig. 3A). Finally, endotoxin measurements for safety in animal trials were performed after the AEX chromatography step. The highest value measured was 3 EU/mL, which was below the acceptable value for vaccination in humans as reported previously (data not shown) (Brito and Singh, 2011).
4. Discussion 3.2. Intranasal immune response
Contemporary strategies in vaccination primarily focus on immune system identification and elimination upon exposure to the virus. This is usually done by Ab identification, where antibodies generated through vaccination can help mobilize elements of the immune system for swift elimination of pathogens. With PEDV, however, the most susceptible subjects (young piglets) have been damaged to too great of an extent during infection in the epithelia. It is therefore critical to stop the virus from entering the mesenteric epithelia, requiring virus neutralization by secreted immunoglobulins in the intestine. For suckling piglets, this requires the transfer of immunoglobulins through colostrum and milk. Although it wasn’t successful in this case, an IN administration may be preferable to help induce a virus-specific secretory IgA response in the lactating sow during the last ten days of gestation. This strategy could increase the amount of virus-specific IgA in the colostrum and milk to provide the lactogenic protection to the suckling piglet. The lack of immune response in the IN administered groups is likely due to a low contact time between the vaccine and the epithelia
ELISA analysis of serum samples was performed for ΔHBcAg first, as a measure of overall immune response. Ab titers to ΔHBcAg in the IN group showed a poor Serum IgG response as well as serum IgA and fecal IgA responses (Fig. 4A, C, E, respectively). These data indicate that the IN administration resulted in a poor overall immune response. The highest serum IgG response came from the ΔHBcAg groups as expected, but the rest of the vaccines delivered by IN demonstrated very little response (Fig. 4A). The same pattern is true in the fecal samples, where there is only a significant difference between the ΔHBcAg group and all other vaccine candidates (Fig. 4E). There was no statistical significance between any of the vaccine candidate groups for serum IgA titers to the backbone protein (Fig. 4C). This result may be due to how low the overall serum IgA titers were in the intranasally administered groups. The titers to the ΔHBcAg coated plates were low enough in the IN groups that other analysis of the serum samples was not performed. 5
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Fig. 3. Transmission electron microscopy was used to elucidate the assembly of each vaccine candidate. (A) ΔHBcAg, (B) HBcAg + S1, (C) HBcAg + S2), (D) HBcAg + S3, (E) HBcAg + M, and (F) HBcAg + S1S2S3 M.
Monoclonal antibodies (mAbs) made and purified from the injection of the spike protein from PEDV have indicated that mAbs containing high titers to portions of the protein containing the YSNIGVCK (S1) motif have a much higher virus neutralization capability than mAbs with high titers to peptide sequences containing either the SQYGQVKI (S2) or the GPRLQPY (S3) motifs (Okda et al., 2017). Though most mAbs produced in that study indicated that there was some neutralization activity, the reduced VN titers may indicate that they are less suitable targets in a subunit vaccination strategy for PEDV. The relatively high virus titers used in the VN testing during this experiment may have simply overwhelmed antibody populations with lower utility in neutralization. It is important to note that mice treated with HBcAg + S2 cannot be included in the data to support this hypothesis. The HBcAg + S2 vaccine was originally designed to have the neutralizing antibodies from the CV777 strain originally found in Denmark. However, many of the strains in the recent (2013) outbreak in the US are phylogenetically distant from the original strain when arranged based on the genome coding for the spike protein (Carvajal et al., 2015; Lee, 2015). Indeed, sequence data from Indiana based strains during the 2013 outbreak such as that used for the assay confirms that the neutralizing “S2” epitope sequence is actually 756SQSGQVKI771 instead of 756 SQYGQVKI771 as was used in the vaccine design. This oversight can be easily changed, possibly allowing for a more effective multivalent vaccine candidate. It was interesting that the HBcAg + S1S2S3 M vaccine candidate was able to neutralize the same amount of PEDV on a per dose basis as the HBcAg + S1 candidate. With four epitopes inserted into the MIR of the ΔHBcAg, it could be hypothesized that the S1 epitope would have a 1:4 chance of interaction with a B-cell receptor. Perhaps the inclusion of multiple B-cell epitopes in the MIR increases the pathogen associated molecular patterns (PAMPS) recognized by the immune system, and therefore increases the overall immunogenicity of the VLP. This phenomenon may be of use in the design of future vaccine candidates. If the
tissue. The introduction of a polymer, such as chitosan, in the formulation of the vaccines could allow the VLPs to adhere to the epithelial surface for a longer amount of time. An increase in contact time would then promote the internalization of the proteins and possibly increase the immune response (Wang et al., 2015; Smith et al., 2014). One important finding was that there was no difference in neutralizing Ab concentration between the monovalent HBcAg + S1 vaccine candidate and the multivalent HBcAg + S1S2S3 M vaccine candidate. Individual epitope titers as measured by ELISA indicated that the HBcAg + S1S2S3 M vaccine candidate was able to produce comparable specific antibody levels as the vaccine candidates containing the single epitopes. Given only the ELISA data, one might be tempted to conclude that the HBcAg + S1S2S3 M vaccine candidate could be much more effective compared to the other proteins. The ELISA data indicates that HBcAg + S1S2S3 M induced a higher overall immune response because of its ability to induce an equal epitope-specific titer in mice at the same dosage. Inclusion of multiple epitopes could also have the added benefit of providing a more diverse immune response as well, allowing possible protection from multiple strains of the virus if mutations were to occur in the epitope regions. Neutralization data, however, indicates that there is a more complicated phenomenon. A second important finding was that only two of the candidates were able to successfully neutralize virus using the assay as described. This may be due to the amount of virus that is used in the assay’s execution, or the genotype of the virus itself. It is hypothesized that Abs corresponding to the S1 epitope are better at neutralizing the virus than Abs to the other epitopes. In this experiment, each individual vaccine candidate had a significantly higher ELISA titer to the epitope insertion than the negative controls, but there was a lack of VN response in the majority of the vaccine candidates. This discrepancy may be due to something as simple as conformational changes in the neutralizing motifs based on viral genotypes (Liu et al., 2017). Another possible mechanism for prevention of neutralization may simply be efficacy. 6
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Fig. 4. Preliminary analysis of immune response was performed using an ELISA assay for antibodies to ΔHBcAg. (A) Serum IgG Titers for IN Administration, (B) Serum IgG Titers for IP Administration, (C) Serum IgA titers for IN Administration, (D) Serum IgA Titers for IP Administration, (E) Fecal IgA titers for IN Administration, and (F) Fecal IgA titers for IP Administration. Each value is compared to a PBS negative control group on each plate. Error bars represent the standard error of the measurements. (* = P ≤ 0.05, ** = P ≤ 0.01, *** = P ≤ 0.001).
and enhance the immune response to the insert (Yin et al., 2014). It may therefore be possible to modify the backbone protein, maintaining vaccine efficacy while reducing the exposed epitopes from HBcAg.
inclusion of multiple conserved B-cell epitopes raises the overall immunogenicity of the vaccine without depleting its ability to produce neutralizing antibodies, then perhaps this strategy could be employed to produce a vaccine that infers protection to both suckling piglets as well as adult pigs. One possible pitfall to using the HBcAg backbone protein might be the prevalence of swine hepatitis B virus (SHBV). Recent evidence suggests this prevalence may be as high as 25% in agricultural pigs (Li et al., 2010). However, another study has indicated that the presence of anti-HBcAg Abs in sows may be closer to 12% (Song et al., 2015). There is therefore concern that the presence of these antibodies in a pregnant sow may cause the elimination of the vaccine through previous immunity, reducing its efficacy. One possible strategy to combat this phenomenon may be through simple redesign of the vaccine. The elimination of key amino acids in the sequence of the backbone have been shown to reduce immunity to the HBcAg portion of the protein
5. Conclusions The preceding data indicate that the HBcAg VLP platform shows promise as an effective tool in a vaccine strategy toward PEDV. Neutralization of a strain of PEDV from the more recent outbreak corroborates previous identification of the YSNIGVCK motif from the Sprotein in PEDV. ELISA titers to three other B-cell epitopes indicate that though they are able to produce significant Abs, the Abs produced may have limited neutralization of high titers of virus. There seemed to be no disadvantage to the inclusion of multiple epitopes in the MIR of HBcAg on viral neutralization, indicating that the multivalent strategy might allow for an effective vaccine used for herd immunity as well as 7
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Fig. 5. ELISA was performed on samples from 42 days post inoculation with EFP proteins containing the individual epitopes as coating proteins to test the immune response to the inserted epitopes. All samples were tested for an immune response to each epitope to ensure there was no cross-reactivity. Coating peptides are as follows: (A) EFP-S1, (B) EFPS2, (C) EFP-S3, and (D) EFP-M. Each value is compared to a PBS negative control group on each plate. Error bars represent the standard error of the measurements. (* = P ≤ 0.05, ** = P ≤ 0.01, *** = P ≤ 0.001).
lactogenic protection. Acknowledgement We thank the generous financial support by Smithfield Foods and Murphy-Brown LLC and the insightful discussion with their scientists, including Drs. Terry Coffey, Perry Harms, Joe Fent, Jeremy Pittman, and Marlin Hoogland, especially Dr. Terry Coffey, throughout the project period. References Alonso, C., Goede, D.P., Morrison, R.B., Davies, P.R., Rovira, A., Marthaler, D.G., Torremorell, M., 2014. Evidence of infectivity of airborne porcine epidemic diarrhea virus and detection of airborne viral RNA at long distances from infected herds. Vet. Res. 45, 73. Audibert, F.M., Przewlocki, G., Leclerc, C., Jolivet, M., Gras-Masse, H., Tartar, A., Chedid, L., 1984. Enhancement by murabutide of the immune response to natural and synthetic hepatitis B surface antigens. Infect. Immun. 45, 261–266. Barreto-Vieira, D.F., Barth, O.M., 2015. Negative and Positive Staining in Transmission Electron Microscopy for Virus Diagnosis. Bottcher, B., Wynne, S.A., Crowther, R.A., 1997. Determination of the fold of the core protein of hepatitis B virus by electron cryomicroscopy. Nature 386, 88–91. Brito, L.A., Singh, M., 2011. Acceptable levels of endotoxin in vaccine formulations during preclinical research. J. Pharm. Sci. 100, 34–37. Carvajal, A., Argüello, H., Martínez-Lobo, F.J., Costillas, S., Miranda, R., de Nova, P.J.G., Rubio, P., 2015. Porcine epidemic diarrhoea: new insights into an old disease. Porcine Health Manage. 1, 12. Chen, Q., Li, G., Stasko, J., Thomas, J.T., Stensland, W.R., Pillatzki, A.E., Gauger, P.C., Schwartz, K.J., Madson, D., Yoon, K.-J., 2014. Isolation and characterization of porcine epidemic diarrhea viruses associated with the 2013 disease outbreak among swine in the United States. J. Clin. Microbiol. 52, 234–243. Cima, G., 2014. PED virus reinfecting US herds. Virus estimated to have killed 7 millionplus pigs. J. Am. Vet. Med. Assoc. 245, 166.
Fig. 6. A virus neutralization assay was run on samples from the 42nd day post inoculation. Error bars represent the standard error of the measurements. (* = P ≤ 0.05, ** = P ≤ 0.01, *** = P ≤ 0.001).
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